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Szabo, K.;  Mitrea, L.;  Călinoiu, L.F.;  Teleky, B.;  Martău, G.A.;  Plamada, D.;  Pascuta, M.S.;  Nemeş, S.;  Varvara, R.;  Vodnar, D.C. Polyphenols in Apple-Processing By-Products. Encyclopedia. Available online: https://encyclopedia.pub/entry/37515 (accessed on 03 December 2024).
Szabo K,  Mitrea L,  Călinoiu LF,  Teleky B,  Martău GA,  Plamada D, et al. Polyphenols in Apple-Processing By-Products. Encyclopedia. Available at: https://encyclopedia.pub/entry/37515. Accessed December 03, 2024.
Szabo, Katalin, Laura Mitrea, Lavinia Florina Călinoiu, Bernadette-Emőke Teleky, Gheorghe Adrian Martău, Diana Plamada, Mihaela Stefana Pascuta, Silvia-Amalia Nemeş, Rodica-Anita Varvara, Dan Cristian Vodnar. "Polyphenols in Apple-Processing By-Products" Encyclopedia, https://encyclopedia.pub/entry/37515 (accessed December 03, 2024).
Szabo, K.,  Mitrea, L.,  Călinoiu, L.F.,  Teleky, B.,  Martău, G.A.,  Plamada, D.,  Pascuta, M.S.,  Nemeş, S.,  Varvara, R., & Vodnar, D.C. (2022, December 01). Polyphenols in Apple-Processing By-Products. In Encyclopedia. https://encyclopedia.pub/entry/37515
Szabo, Katalin, et al. "Polyphenols in Apple-Processing By-Products." Encyclopedia. Web. 01 December, 2022.
Polyphenols in Apple-Processing By-Products
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Polyphenols of plant origin are a broad family of secondary metabolites that range from basic phenolic acids to more complex compounds such as stilbenes, flavonoids, and tannins, all of which have several phenol units in their structure. Considerable health benefits, such as having prebiotic potential and cardio-protective and weight control effects, have been linked to diets based on polyphenol-enriched foods and plant-based products, indicating the potential role of these substances in the prevention or treatment of numerous pathologies. The most representative phenolic compounds in apple pomace are phloridzin, chlorogenic acid, and epicatechin, with major health implications in diabetes, cancer, and cardiovascular and neurocognitive diseases. 

phenolic compounds health effects apple-processing by-products

1. Introduction

By-products of agro-industrial provenance and food waste are severe global concerns, particularly in many developed countries [1]. Food consumption has increased as a consequence of urbanization, population expansion, and economic growth, and it remains a consistent issue worldwide in the long run [2][3]. The most bothersome sectors are the wheat flour production, apple juice production, and tomato-processing industries, which generate massive amounts of residues, as a result of the extensive yearly processed tonnage. On the other hand, the low cost and straightforward availability of this residual biomass shelter the economic prospects of its potentially valuable components [4].

2. Polyphenols in Apple-Processing By-Products

Apples are one of the most consumed fruits worldwide, both in industry and at the individual population level [5]. Approximately 11 million metric tons of apples is produced and used annually in the apple-processing industry and alcoholic beverage production in Europe [6]. Apple pomace is one of the most widely produced agrifood wastes, with an annual production rate of about 4 million tons worldwide [7]. The recovery rate for this by-product, however, is modest. Pomace is frequently discarded and dumped in landfills as waste, which causes environmental issues and presents a potential risk to public health [3][8].
The amount of pomace resulting after apple processing can be reused in biotechnological routs as a substrate for the production of different compounds, such as flavoring compounds, pigments, fuel, and citric acid, or as raw materials for the extraction of fibers and phenolic compounds [9][10][11][12].
From a nutritional point of view, apple pomace is a by-product rich in fibers, vitamins, minerals, phenolic compounds, and pigments [13]. All these macronutrients have a significant role in the human organism through their effects on metabolism. Therefore, apple pomace has attracted researchers’ consideration, as well as stakeholders’ attention, by virtue of its valuable composition and by presenting suitable properties for further sustainable use [14].
The nutritional profile of apple pomace is mainly represented by phenolic compounds, carbohydrates, and fibers, as presented in Table 1. These constituents can help treat gastrointestinal disorders, decrease serum triglycerides and LDL-cholesterol, and regulate glycemia [15][16]. All these effects in the human organism can be explained through their high concentration of the beneficial compounds mentioned above, primarily exerting anti-inflammatory and antioxidant roles [17].
Table 1. The nutritional and polyphenolic profile of apple pomace 1 [18].
1 Values represent mean ± standard deviation, based on [18]; 2 nitrogen to protein conversion factor was 5.7.
In addition to the benefits, the consumption of apple pomace may raise questions associated with toxicity when it comes to its applicability in the food industry [19], with seeds representing 4–5% of the apple pomace [20]. Apple seeds contain a plant toxin called cyanogenic glycoside amygdalin, which can interact with digestive enzymes, resulting in the release of hydrogen cyanide. This toxin can cause different symptoms, from mild symptoms such as dizziness to severe symptoms such as paralysis and coma [21]. However, to reach poisoning levels, the ingested quantity must be significantly high; more exactly, between 83–500 apple seeds are needed to reach the poisoning level, or the person must consume more than 800 g of apple pomace [7][22]. Studies on apple seed oil have confirmed the safety of its use, as the limit was found to be below the toxicity level [23].
Phenolic compounds are concentrated mainly in the core, seeds, peel, calyx, and stem, as well as in smaller amounts in the pulp, highlighting how apple pomace can be valorized through its high amount of antioxidant compounds. As shown in Figure 1, the total phenolic content of seeds has a higher value compared with the pulp, followed by the peel, both being part of apple pomace.
Figure 1. Distribution of phenolic compounds in apple fruit, according to Feng et al. [24]. TPC—total phenolic content; DW—dry weight.
The predominant phenolic compound families in apple pomace are dihydrochalcones, procyanidins, flavan-3-ol monomers, flavonols, anthocyanidins, and hydroxycinnamic acids. The most representative compounds are phlorizin from the dihydrochalcones family, chlorogenic acid from the hydroxycinnamic acids family, and epicatechin from the flavan-3-ol monomer family [25].
One of the representative phenolic compounds in apples and, remarkably, apple pomace, is phlorizin (Figure 2A). As the main compound from the dihydrochalcone family, the amount of phlorizin in apple pomace is approximately 1.6 mg/g dry weight, highlighted in a study by Lavelli et al. on the stability of phenolic compounds in apple pomace [26]. Phlorizin is used as a marker of apple varieties and is mainly concentrated in apple seeds. This polyphenol is also used as a reliable marker for spotting the presence of apples, a less expensive alternative compared with the reported fruits [27].
Figure 2. The chemical structure of the predominant phenolic compounds identified in apple pomace: chlorogenic acid (A); epicatechin (B); phlorizin (C). Source: ChemDraw Software.
Nevertheless, it also acts as a strong antioxidant, anti-inflammatory, and antimicrobial compound [28][29]. Regarding its benefits, phlorizin exerts several health benefits, mainly in diabetes, due to its ability to alter the glucose absorbed and excreted. A recent study illustrated that the intestine and kidney’s sodium/glucose cotransporters are specifically and competitively inhibited by phlorizin. In addition, postprandial hyperglycemia therapy in diabetes and other associated illnesses, such as obesity, may benefit from this characteristic [30]. A study conducted on streptozotocin-induced diabetic mice showed that a diet containing 0.5% phlorizin significantly improves the exacerbated elevations in blood glucose levels [31][32]. Another health benefit can be seen in colitis, where it acts as a protective compound for the intestinal brush border [33].
Chlorogenic acid (Figure 2B) is representative in the peel and flesh of apples compared with their seeds. Chlorogenic acid is a powerful antioxidant known for counteracting pathologies caused by oxidative processes [34][35]. A study conducted on the improvement of mood and cognition in the elderly showed enhanced results after the administration of enriched decaffeinated coffee with chlorogenic acid, displaying that the consumption of products containing chlorogenic acid can help in the treatment of neuro-cognitive diseases [36]. Besides the benefits mentioned previously, chlorogenic acid can also confer positive effects by lowering blood pressure, confirmed in a randomized trial involving healthy volunteers after the administration of 400 mg chlorogenic acid in 400 mL low-nitrate water. This effect can be explained by the ability of phenolic compounds to increase nitric oxide, which improves cardiovascular health [37].
The third phenolic compound found in apple pomace in smaller amounts is epicatechin (Figure 2C). Besides all its fulfilled roles (e.g., antioxidation, anti-inflammation), epicatechin can exert its role in diabetes, cancer, and cardiovascular disease, acting as a neuroprotective compound, and it improves muscle performance [38]. Cilleros et al. showed, in an in vitro study, the effect of epicatechin in regulating glucose uptake and bolstering the insulin signaling pathway [39]. A study conducted on human monocytic cells (THP1 cells) showed similar results regarding the beneficial effects of epicatechin in diabetes through the attenuation of high-glucose-induced inflammation [40].

References

  1. Gu, B.; Zhang, X.; Bai, X.; Fu, B.; Chen, D. Four steps to food security for swelling cities. Nature 2019, 566, 31–33.
  2. Szabo, K.; Teleky, E.B.; Ranga, F.; Simon, E.; Pop, L.O.; Babalau-Fuss, V.; Kapsalis, N.; Cristian, D. Bioaccessibility of microencapsulated carotenoids, recovered from tomato processing industrial by-products, using in vitro digestion model. LWT 2021, 152, 112285.
  3. Martău, G.A.; Teleky, B.E.; Ranga, F.; Pop, I.D.; Vodnar, D.C. Apple Pomace as a Sustainable Substrate in Sourdough Fermentation. Front. Microbiol. 2021, 12, 3850.
  4. Iriondo-Dehond, M.; Miguel, E.; Del Castillo, M.D. Food byproducts as sustainable ingredients for innovative and healthy dairy foods. Nutrients 2018, 10, 1358.
  5. Francini, A.; Sebastiani, L. Phenolic compounds in apple (Malus x domestica borkh.): Compounds characterization and stability during postharvest and after processing. Antioxidants 2013, 2, 181–193.
  6. Bchir, B.; Karoui, R.; Danthine, S.; Blecker, C.; Besbes, S.; Attia, H. Date, Apple, and Pear By-Products as Functional Ingredients in Pasta: Cooking Quality Attributes and Physicochemical, Rheological, and Sensorial Properties. Foods 2022, 11, 1393.
  7. Gołębiewska, E.; Kalinowska, M.; Yildiz, G. Sustainable Use of Apple Pomace (AP) in Different Industrial Sectors. Materials 2022, 15, 1788.
  8. Lyu, F.; Luiz, S.F.; Azeredo, D.R.P.; Cruz, A.G.; Ajlouni, S.; Ranadheera, C.S. Apple pomace as a functional and healthy ingredient in food products: A review. Processes 2020, 8, 319.
  9. Ricci, A.; Cirlini, M.; Guido, A.; Liberatore, C.M.; Ganino, T.; Lazzi, C.; Chiancone, B. From byproduct to resource: Fermented apple pomace as beer flavoring. Foods 2019, 8, 309.
  10. Le Deun, E.; Van Der Werf, R.; Le Bail, G.; Le Quéré, J.M.; Guyot, S. HPLC-DAD-MS Profiling of Polyphenols Responsible for the Yellow-Orange Color in Apple Juices of Different French Cider Apple Varieties. J. Agric. Food Chem. 2015, 63, 7675–7684.
  11. Molinuevo-Salces, B.; Riaño, B.; Hijosa-Valsero, M.; González-García, I.; Paniagua-García, A.I.; Hernández, D.; Garita-Cambronero, J.; Díez-Antolínez, R.; García-González, M.C. Valorization of apple pomaces for biofuel production: A biorefinery approach. Biomass Bioenergy 2020, 142, 105785.
  12. Shojaosadati, S.A.; Babaeipour, V. Citric acid production from apple pomace in multi-layer packed bed solid-state bioreactor. Process Biochem. 2002, 37, 909–914.
  13. Rabetafika, H.N.; Bchir, B.; Blecker, C.; Richel, A. Fractionation of apple by-products as source of new ingredients: Current situation and perspectives. Trends Food Sci. Technol. 2014, 40, 99–114.
  14. Sato, M.F.; Vieira, R.G.; Zardo, D.M.; Falcão, L.D.; Nogueira, A.; Wosiacki, G. Apple pomace from eleven cultivars: An approach to identify sources of bioactive compounds. Acta Sci. Agron. 2010, 32, 29–35.
  15. Kasprzak-Drozd, K.; Oniszczuk, T.; Stasiak, M.; Oniszczuk, A. Beneficial effects of phenolic compounds on gut microbiota and metabolic syndrome. Int. J. Mol. Sci. 2021, 22, 3715.
  16. Sergent, T.; Piront, N.; Meurice, J.; Toussaint, O.; Schneider, Y.J. Anti-inflammatory effects of dietary phenolic compounds in an in vitro model of inflamed human intestinal epithelium. Chem. Biol. Interact. 2010, 188, 659–667.
  17. Skinner, R.C.; Gigliotti, J.C.; Ku, K.M.; Tou, J.C. A comprehensive analysis of the composition, health benefits, and safety of apple pomace. Nutr. Rev. 2018, 76, 893–909.
  18. Wang, X.; Kristo, E.; LaPointe, G. The effect of apple pomace on the texture, rheology and microstructure of set type yogurt. Food Hydrocoll. 2019, 91, 83–91.
  19. Gumul, D.; Ziobro, R.; Korus, J.; Kruczek, M. Apple pomace as a source of bioactive polyphenol compounds in gluten-free breads. Antioxidants 2021, 10, 807.
  20. Walia, M.; Rawat, K.; Bhushan, S.; Padwad, Y.S.; Singh, B. Fatty acid composition, physicochemical properties, antioxidant and cytotoxic activity of apple seed oil obtained from apple pomace. J. Sci. Food Agric. 2014, 94, 929–934.
  21. Bolarinwa, I.F.; Orfila, C.; Morgan, M.R.A. Determination of amygdalin in apple seeds, fresh apples and processed apple juices. Food Chem. 2015, 170, 437–442.
  22. Opyd, P.M.; Jurgoński, A.; Juśkiewicz, J.; Milala, J.; Zduńczyk, Z.; Król, B. Nutritional and health-related effects of a diet containing apple seed meal in rats: The case of amygdalin. Nutrients 2017, 9, 1091.
  23. Montañés, F.; Catchpole, O.J.; Tallon, S.; Mitchell, K.A.; Scott, D.; Webby, R.F. Extraction of apple seed oil by supercritical carbon dioxide at pressures up to 1300 bar. J. Supercrit. Fluids 2018, 141, 128–136.
  24. Feng, S.; Yi, J.; Li, X.; Wu, X.; Zhao, Y.; Ma, Y.; Bi, J. Systematic Review of Phenolic Compounds in Apple Fruits: Compositions, Distribution, Absorption, Metabolism, and Processing Stability. J. Agric. Food Chem. 2021, 69, 7–27.
  25. Pollini, L.; Cossignani, L.; Juan, C.; Mañes, J. Extraction of phenolic compounds from fresh apple pomace by different non-conventional techniques. Molecules 2021, 26, 4272.
  26. Lavelli, V.; Corti, S. Phloridzin and other phytochemicals in apple pomace: Stability evaluation upon dehydration and storage of dried product. Food Chem. 2011, 129, 1578–1583.
  27. Hrubá, M.; Baxant, J.; Čížková, H.; Smutná, V.; Kovařík, F.; Ševčík, R.; Hanušová, K.; Rajchl, A. Phloridzin as a marker for evaluation of fruit product’s authenticity. Czech J. Food Sci. 2021, 39, 49–57.
  28. Rana, S.; Gupta, S.; Rana, A.; Bhushan, S. Functional properties, phenolic constituents and antioxidant potential of industrial apple pomace for utilization as active food ingredient. Food Sci. Hum. Wellness 2015, 4, 180–187.
  29. Táborský, J.; Sus, J.; Lachman, J.; Šebková, B.; Adamcová, A.; Šatínský, D. Dynamics of phloridzin and related compounds in four cultivars of apple trees during the vegetation period. Molecules 2021, 26, 3816.
  30. Najafian, M.; Jahromi, M.Z.; Nowroznejhad, M.J.; Khajeaian, P.; Kargar, M.M.; Sadeghi, M.; Arasteh, A. Phloridzin reduces blood glucose levels and improves lipids metabolism in streptozotocin-induced diabetic rats. Mol. Biol. Rep. 2012, 39, 5299–5306.
  31. Kamdi, S.P.; Badwaik, H.R.; Raval, A.; Ajazuddin; Nakhate, K.T. Ameliorative potential of phloridzin in type 2 diabetes-induced memory deficits in rats. Eur. J. Pharmacol. 2021, 913, 174645.
  32. Masumoto, S.; Akimoto, Y.; Oike, H.; Kobori, M. Dietary Phloridzin Reduces Blood Glucose Levels and Reverses Sglt1 Expression in the Small Intestine in Streptozotocin-lnduced Diabetic Mice. J. Agric. Food Chem. 2009, 57, 4651–4656.
  33. Lu, Y.Y.; Liang, J.; Chen, S.X.; Wang, B.X.; Yuan, H.; Li, C.T.; Wu, Y.Y.; Wu, Y.F.; Shi, X.G.; Gao, J.; et al. Phloridzin alleviate colitis in mice by protecting the intestinal brush border and improving the expression of sodium glycogen transporter 1. J. Funct. Foods 2018, 45, 348–354.
  34. Fang, Y.Z.; Yang, S.; Wu, G. Free radicals, antioxidants, and nutrition. Nutrition 2002, 18, 872–879.
  35. Upadhyay, R.; Mohan Rao, L.J. An Outlook on Chlorogenic Acids-Occurrence, Chemistry, Technology, and Biological Activities. Crit. Rev. Food Sci. Nutr. 2013, 53, 968–984.
  36. Cropley, V.; Croft, R.; Silber, B.; Neale, C.; Scholey, A.; Stough, C.; Schmitt, J. Does coffee enriched with chlorogenic acids improve mood and cognition after acute administration in healthy elderly? A pilot study. Psychopharmacology 2012, 219, 737–749.
  37. Mubarak, A.; Catherine, P.B.; Liu, A.H.; Considine, M.J.; Rich, L.; Mas, E.; Croft, K.D.; Hodgson, J.M. Acute effects of chlorogenic acid on nitric oxide status, endothelial function and blood pressure in healthy volunteers: A randomised trial. J. Agric. Food Chem. 2012, 60, 9130–9136.
  38. Qu, Z.; Liu, A.; Li, P.; Liu, C.; Xiao, W.; Huang, J.; Liu, Z.; Zhang, S. Advances in physiological functions and mechanisms of (-)-epicatechin. Crit. Rev. Food Sci. Nutr. 2021, 61, 211–233.
  39. Cilleros, D.Á.; Martín, M.Á.; Ramos, S. (−)-Epicatechin and the colonic 2,3-dihydroxybenzoic acid metabolite regulate glucose uptake, glucose production, and improve insulin signalling in renal NRK-52E cells. Mol. Nutr. Food Res. 2018, 62, 1700470.
  40. Cordero-Herrera, I.; Chen, X.; Ramos, S.; Devaraj, S. (−)-Epicatechin attenuates high-glucose-induced inflammation by epigenetic modulation in human monocytes. Eur. J. Nutr. 2017, 56, 1369–1373.
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